Method for creating osmotic-pressure-tolerant plant

ABSTRACT

A method for producing salt-tolerant and/or osmotolerant plants, which comprises the step of transforming a plant with a recombinant vector carrying a gene encoding choline oxidase, as well as the salt-tolerant and/or osmotolerant plants produced by said method or a progeny thereof having the same properties.

FIELD OF THE INVENTION

This invention relates to a method for producing plants with novel properties, more specifically, a method for producing salt-tolerant and/or osmotolerant plants which are highly resistant to environmental stresses.

DESCRIPTION OF THE PRIOR ART

One effective way to prevent global warming is greening of uncultivated soils such as desert or salt-accumulated soil. As a means therefor, the development of plants which are resistant to environmental stresses in combination with an engineering solution such as irrigation plays an important role in controlling encroachment of desert, promoting greening and preventing global warming.

Salt accumulation causes the following damages: (1) accumulated salt lowers the water potential in soil to prevent plants from absorbing water; (2) the salt absorbed (penetrated) into plants disturbs their metabolism; (3) salt inhibits the absorption of other ions necessary for viability (Sato, F., Plant Cell Engineering, Supplement, “Environmental Problems and Phytobiotechnology”, pp. 33-39, 1994). Especially, the inhibition of water absorption causes plants to lose turgor pressure and close stoma. Thus, photosynthesis is deteriorated and growth is seriously inhibited.

Plants have evolved various mechanisms to adapt themselves to such environments. In a simple adaptation model, plant cells keep an osmotic difference between the inside and outside of the cells in some way, and restore turgor by water absorption. For example, halobacteria, which are not plants however, keep an osmotic balance between the inside and outside by accumulating salt in the cells. In this case, however, it is difficult to adapt them to environmental (osmotic) changes, because intracellular metabolic enzymes per se need to be salt-tolerant.

Therefore, a better adaptation mechanism is the synthesis of a specific compound called “compatible solute” for keeping an intracellular osmosis depending on extrinsic osmotic changes as many salt-tolerant plants do so.

As the compatible solute, bipolar compounds such as glycinebetaine or proline and polyols such as pinitol, sorbitol or mannitol are known. These compounds are characterized by low molecular weight, high water-solubility, low metabolizability, non-influence on metabolism, etc., and are suitable for osmoregulation.

Among others, glycinebetaine (hereinafter referred to as betaine) is noted as a compatible solute found in plants and bacteria which are adaptable to salt-accumulated and/or water-deficient environment. Betaine is thought as a compatible solute found in higher plants such as Chenopodeaceae, Gramineae, Solanaceae, as well as cyanobacteria, Escherichia coli, etc. (for example, see Rhodes, D. and Hanson, A. D., Annu. Rev. Plant Physiol. Plant Mol. Biol. 44:357-3584, 1993). Betaine is an osmoprotective substance which keeps an osmotic balance with environments (Robinson, S. P. and Jones, G. P., Aust. J. Plant Physiol. 13:659-668, 1986) and prevents the dissociation of soluble enzymes due to high salt concentration (Gabbay-Azaria et al., Arch. Biochem. Biophys. 264:333-339, 1988). In addition, betaine can protect photosystem II complex against high salt concentration by stabilization of neighboring proteins and manganese cluster within photosynthetic oxygen-evolving complex (for example, see Murata et al., FEBS Lett. 296:187-189, 1992).

In Escherichia coli and spinach (Spinacia oleracea), betaine is biosynthesized from choline via two steps of oxidation as shown in FIG. 1. E. coli contains two dehydrogenases; one is a membrane-bound oxygen-dependent choline dehydrogenase which oxidizes choline to betainealdehyde (Landfald, B. and Strom, A., J. Bacteriol. 165:849-855, 1986), and the other is a soluble NAD-dependent betainealdehyde dehydrogenase which oxidizes betainealdehyde to betaine (Falkenberg, P. and Strom, A. R., Biochim. Biophys. Acta. 1034:253-259, 1990). In higher plants, it has been demonstrated that betaine is synthesized in the chloroplasts via a similar pathway to E. coli. In spinach (Spinacia oleracea), the first step of oxidation is catalysed by a ferredoxin-dependent choline monooxygenase (Brouquisse, R. et al., Plant Physiol. 90:322-329, 1989) and an NAD-dependent betainealdehyde dehydrogenase which catalyzes the second step of oxidation (Weretilnyk, E. A. et al., Planta. 178:342-352, 1989) has already been isolated. These plants were found to increase the activities of the both enzymes and thereby the amount of betaine under salt stress (for example, see Hanson, A. D. et al., Proc. Natl. Acad. Sci. U.S.A. 82:3678-3682, 1985).

Alternatively, choline oxidase from the gram-positive soil bacterium Arthrobacter globiformis is able to oxidize choline to betaine in one-step oxidation reaction (Ikuta, S. et al., J. Biochem. 82:1741-1749, 1977).

Attempts have been made to confer salt tolerance by integrating such two genes as found in E. coli and higher plants or choline oxidase gene into a plant to allow it constantly express these genes (for example, see Nomura M. et al., Plant Physiol. 107:703-708, 1995). However, no success has been achieved so far in obtaining a salt-tolerant and/or osmotolerant plant by integrating such genes into a plant, especially a higher plant expressing them stably.

Choline oxidase is commercially available, but its amino acid sequence has not been determined. Therefore, it would be highly desirable to determine a genetic sequence encoding choline oxidase which can efficiently convert choline into betaine and to integrate it into a plant to allow it to stably express said sequence, whereby producing a plant which is tolerant to environmental (osmotic) changes such as high salt concentration.

SUMMARY OF THE INVENTION

After profound study to solve the above problems, the present inventors succeeded in isolating a novel gene encoding choline oxidase (The Japanese Society of Plant Physiologist, Annual meeting of 1994, the 34th Symposium held Mar. 28-30, 1994) and integrating it into cyanobacteria, brassicaceous and gramineous plants to obtain salt-tolerant and/or osmotolerant plants.

Accordingly, this invention provides a method for producing salt-tolerant and/or osmotolerant plants, which comprises the step of transforming a plant with a recombinant vector carrying a gene encoding choline oxidase, as well as the salt-tolerant and/or osmotolerant plants obtained by said method.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic representation showing the oxidation process from choline to betaine.

FIG. 2A is a schematic representation showing the constructs used for transformation of Synechococcus PCC7942. PAM refers to Synechococcus PCC7942 transformed with pAM1044, and PAMCOD refers to Synechococcus PCC7942 transformed with pAM1044 carrying the codA gene. Dashed arrows indicate the primers used for PCR. Triangles represent the conII promoter. Arrows indicate the orientation of the genes.

FIG. 2B is an SDS-PAGE representation (photograph of electrophoresis) showing the complete replacement of chromosomes by the spectinomycin-resistant gene and codA gene in DNA of Synechococcus PCC7942. Lane a: λ-HindIII/φx174-HaeIII fragment; lane b: the wild-type strain of Synechococcus PCC7942; lane c: the strain PAM; lanes d and e: the strain PAMCOD (lanes b, c and d show the results of PCR with primers 1 and 2, and lane e shows the results of PCR with primers 1 and 3).

FIG. 3 is a Western blot analysis representation (photograph of electrophoresis) showing the expression of choline oxidase in the Synechococcus strains PAM and PAMCOD. Lane a: protein extracts from the strain PAMCOD; lane b: protein extracts from the strain PAM; lane c: purified choline oxidase.

FIG. 4 shows the effect of NaCl on growth. Growth of the Synechococcus strains PAM (◯) and PAMCOD () in the presence of 0.4M NaCl is shown. For comparison, growth of the Synechococcus strains PAM (Δ) and PAMCOD (▴) cultivated on the medium free from NaCl is also shown.

FIG. 5 shows the effect of sorbitol on growth. Growth of the Synechococcus strains PAM (◯) and PAMCOD () in the presence of 0.8M sorbitol is shown. For comparison, growth of the Synechococcus strains PAM (Δ) and PAMCOD (▴) cultivated on the medium free from sorbitol is also shown.

FIG. 6 shows the effect of NaCl on chlorophyll content. Chlorophyll contents of the Synechococcus strains PAM (◯) and PAMCOD () in the presence of 0.4M NaCl are shown.

FIG. 7 shows the effect of sorbitol on chlorophyll content. Chlorophyll contents of the Synechococcus strains PAM (◯) and PAMCOD () in the presence of 0.8M sorbitol are shown.

FIG. 8 shows the effect of NaCl on photosynthetic activity. Oxygen evolution levels from the Synechococcus strains PAM (◯) and PAMCOD () in the presence of 0.4M NaCl are shown.

FIG. 9 is a schematic representation showing the restriction enzyme map of the codA gene.

FIG. 10 is a schematic representation showing the structure of the binary vector plasmid pGAH/codA used for transformation of Arabidopsis.

FIG. 11 shows Western blot analysis (photograph of electrophoresis) of choline oxidase in soluble fractions of the wild-type and transformant plants of Arabidopsis. Lane 1: choline oxidase from a commercial product of Arthrobacter globiformis (Sigma Chemical Co., St. Louis, Mo., USA); lane 2: soluble fractions of the wild-type plant; lane 3: soluble fractions of a transformant plant.

FIGS. 12A-12B show the effect of NaCl on the growth of Arabidopsis. The wild-type (A) and transformant C1-0 (B) plants in the presence of 60 mM NaCl are shown (photographs showing the morphology of the organisms).

FIG. 13 shows the effect of sorbitol on the growth of Arabidopsis. The wild-type (W) and transformant (T) plants in the presence of 100, 200 and 400 mM sorbitol are shown (photographs showing the morphology of the organisms).

FIG. 14 shows the influence of salt stress on photosynthesis system II in leaves of the wild-type and transformant plants (Arabidopsis). ◯: the wild-type plant incubated under light conditions; : a transformant plant incubated under light conditions; Δ: the wild-type plant incubated under dark conditions; ▴: a transformant plant incubated under dark conditions. Each data represents the average of triplicate runs with standard deviation of ±5%.

FIG. 15 shows the structures of the two chimeric codA genes used for transformation of rice, i.e. 35SINTPcodA and 35SINcodA.

FIG. 16(A-D) shows NMR charts representing betaine accumulation in rice plants of the wild-type strain (FIG. 16B), a transformant (A) (FIG. 16C) not expressing the codA gene, and a transformant (B) (FIG. 16D) expressing the codA gene. In the figure, GB and Ch represent peaks corresponding to betaine and choline, respectively.

FIG. 17(A-B) shows the influence of salt stress on photosynthetic system II activity of the wild-type (FIG. 17A) and transformant (FIG. 17B) rice plants.

DETAILED DESCRIPTION OF THE INVENTION

The gene encoding choline oxidase used in this invention is a gene which encodes a protein capable of converting choline into betaine in a one-step reaction and which may be derived from gram-positive soil bacteria of the genus Arthrobacter. For example, it may be preferably derived from Arthrobacter globiformis and Arthrobacter pascens, especially Arthrobacter globiformis.

The present inventors successfully cloned the codA gene encoding choline oxidase from Arthrobacter globiformis and determined its nucleotide sequence (SEQ ID NO:1). The codA gene contains an open reading frame of 1641 bp, which encodes 547 amino acids. The nucleotide sequence and amino acid sequence of the codA gene are shown as SEQ ID NO. 1 and SEQ ID NO:2.

Plants can be transformed with such a choline oxidase-coding gene integrated into appropriate vectors. Then, the gene can be expressed in the plants by introducing into these vectors an appropriate promoter or a sequence responsible for the expression of character.

Any gene having a nucleotide sequence resulting from addition, deletion or substitution of the nucleotide sequence encoding the amino acid of SEQ ID NO. 1 and SEQ ID NO:2 or a part thereof may be used as the gene according to this invention so far as it encodes a polypeptide showing choline oxidase activity.

According to the method of this invention, salt tolerance and/or osmotolerance can be conferred to a large variety of plants ranging from cyanobacteria to higher plants. Cyanobacteria are widely used as model organisms of higher plants because they have basically the same photosynthetic mechanism as higher plants and they are easily transformed to give the results in a short time. Some transformant-type cyanobacteria readily incorporate foreign DNA into their cells to cause efficient recombination. Such cyanobacteria include Synechococcus PCC7942, Synechococcus PCC6301 (ATCC 27144) and Synechocystis PCC6803 (ATCC 27184) (Protein, Nucleic Acid, Enzyme, Vol.35, No.14, pp.2542-2551, 1991; Crit. Rev. Microbiol. Vol.13, No.1, pp.111-132, 1985).

Higher plants include dicotyledons and monocotyledons. In Examples described below, highly salt-tolerant and/or osmotolerant plants could be obtained from a brassicaceous plant as a dicotyledon, but it is not limitative and other families and genera of dicotyledons may be used. The method of this invention may also be applicable to monocotyledons. It was found that a monocotyledonous plant rice, which originally lacks betaine-synthesizing ability, gained this ability, and therefore salt tolerance after transformation according to the method of this invention.

The vectors into which the choline oxidase-coding gene is integrated and the procedures for transformation and selection of the transformant plant materials can be appropriately chosen dependent on the nature of the plant to be transformed.

For example, plasmids such as pUC303 can be used for cyanobacteria. Then, the transformants having desired properties can be selected by the antibiotics resistant genes inserted into these plasmids. This invention succeeded in obtaining the plants which stably show salt tolerance and/or osmotolerance by transforming the cyanobcterium Synechococcus PCC7942 with the codA gene encoding choline oxidase from Arthrobacter globiformis.

When the Synechococcus PCC7942 transformed with the codA gene was cultivated on a medium supplemented with choline chloride, the Synechococcus was found to take up exogeneously supplied choline and convert it into betaine. In view of the report that choline transport is induced by salt stress in several salt-tolerant bacteria, resulting in accumulation of higher level of betaine (Kaenjak, A. et al., J. Bacteriol. 175:2400-2406, 1993), the influence of salt stress on betaine accumulation was examined by treating the transformant Synechococcus produced by this invention with NaCl at various concentrations. However, the influence of NaCl concentration on betaine accumulation was not significantly observed, suggesting that the transporter for choline uptake in Synechococcus is not specifically induced by salt stress.

It has also been reported that betaine not only acts as an osmoprotectant but also plays an essential role in protection of photosynthetic mechanism in photoautotrophic organisms (Murata, N. et al., FEBS Lett. 296:187-189, 1992). The Synechococcus transformed according to this invention was cultivated in the presence of high concentration NaCl or sorbitol to examine growth, chlorophyll content and photosynthetic activity. As a result, the transformant Synechococcus grew well in the presence of either high concentration salt or sorbitol and also showed the similar results for chlorophyll content and photosynthetic activity, as compared with the control non-transformant in which growth, chlorophyll content and photosynthetic activity were all inhibited. These results mean that excellent salt tolerance and osmotolerance were conferred to the Synechococcus transformed with the gene encoding choline oxidase according to the method of this invention.

Dicotyledons may be transformed by gene introduction technique using protoplasts or a part of tissue. In case of the gene introduction using tissue pieces, the Ti plasmid from Agrobacterium may be used. Tissue pieces of a callused plant may be infected with Agrobacterium bearing protoplasts into which the choline oxidase-coding gene has been integrated, selected by resistance to an antibiotic such as kanamicin, and then differentiated in shoots to give a transformant plant.

In this invention, a salt-tolerant and/or osmotolerant plant was obtained by transforming the brassicaceous plant Arabidopsis thaliana with the choline oxidase-coding gene as follows.

A binary vector plasmid pGAH-codA carrying the codA gene was prepared and integrated into Agrobaterium tumefaciens EHA101 bearing the Ti plasmid. Hypocotyl calli of Arabidopsis were infected with the resultant Agrobacterium EHA101 (pGAH/codA) incorporating the codA gene, then shoots were formed and selected by kanamycin and hygromycin resistance to induce roots and to form seeds. The plants obtained from said heterozygous T2 seeds were self-fertilized to give homozygous T3 individuals, which were sown to form transformant plants. These transformant plants showed that choline oxidase had been transported to the chloroplasts. The transformant plants grew well even in the presence of high concentration sodium chloride or sorbitol.

The monocotyledonous plant rice (Oryza sativa L. cv. Nippon bare) can be transformed with two chimeric codA genes prepared on the plasmid pUC119, which are localised on cytosol or plastide after translation under transcriptional contol of the cauliflower mosaic virus 35S promoter. Both of the chimeric genes include a rice-derived intron in the 5′ non-translated sequence in order to enhance the expression.

The transformant rice can be produced by the following procedure. Namely, the transformant plant can be obtained by introducing said chimeric codA genes into suspension culture cells from scutellum calli of rice seeds together with the selection marker hygromicin-resistant gene by a particle gun device, then selecting the transformed calluses based on the antibiotics resistance, and redifferentiating them into a plant.

Although the wild-type rice lacks betaine-synthesizing ability, the rice transformed by the method of this invention gained betaine-synthesizing ability. The transformant rice expressing the codA gene grew equally to the non-transformed plant without showing any apparent abnormality under the both of geoponic and hydroponic conditions. This may conclude that hydrogen peroxide formed as a by-product of betaine synthesis was efficiently detoxified in the cells.

Moreover, salt tolerance tests of the transformants cultivated on water with NaCl showed that the inhibition of photosynthetic activity in the transformants was slower than observed in the wild type. This is the first case in which rice has gained betaine-synthesizing ability through a genetic engineering procedure.

These results show that various plants transformed with recombinant vectors carrying the gene encoding choline oxidase have an excellent salt tolerance.

According to this invention, salt-tolerant and/or osmotolerant transformant plants which are highly resistant to environmental stresses can be obtained. The range of plants to which can be conferred salt tolerance and/or osmotolerane by the method of this invention is very wide, from cyanobacteria to higher plants. Especially, this invention is the first case in which salt-tolerant and/or osmotolerant transformant plants were obtained from monocotyledons including most of main crops and expected to be applied in a very wide range.

The following examples further explain this invention in detail, but are not intended to limit the scope of this invention.

EXAMPLES Example 1 Transformation of the Cyanobacterium Synechococcus PCC7942 with the codA Gene

(1) Cloning of the codA Gene

The choline oxidase gene was isolated from Arthrobacter globiformis by the method described in the Abstracts of Oral Reports in the abstracts, the 34th annual meeting of the Japanese Society of Plant Physiologists, 1994. In brief, 1) choline oxidase is fragmented with cyanogen bromide, 2) the N-terminal amino acid sequences of appropriate fragments are determined, 3) an appropriate part is selected from said amino acid partial sequences to synthesize oligonucleotides corresponding thereto, 4) a partial sequences of the choline oxidase gene is amplified by PCR (Polymerase Chain Reaction) using these oligonucleotides as primers, 5) the amplified partial sequence of the choline oxidase gene is used as a probe to screen the genomic DNA library of Arthrobacter globiformis.

Thus obtained positive clones were subcloned into the plasmid pBluescript (SK⁺) (Stratagene) to isolate positive clones, which were subjected to Southern blot analysis. A 3.6 kbp XbaI-XhoI fragment which hybridized to said probe was subcloned into pBluescript and mapped with restriction enzymes. The nucleotide sequence of the region spanning from the first SalI-site to XhoI-site (about 2.5 kbp) was determined.

The results showed that the choline oxidase gene contains an open reading frame of 1641 bp which encodes a polypeptide of 547 amino acid residues. The amino acid sequence and the nucleotide sequence of the choline oxidase-coding gene are shown as SEQ ID NO. 1 and SEQ ID NO:2.

(2) Transformation of Synechococcus PCC7942 with the codA Gene

The plasmid pBluescript carrying the codA gene was digested with BstEII (position −40 from the initiation of translation) and SmaI (downstream of the stop codon) restriction enzymes. The BstE II-cohesive end was filled in by Klenow fragment (Takara, Tokyo, Japan). The blunt-ended fragment containing the coding region of the codA gene and a putative ribosome binding site was inserted into the SmaI site of the plasmid pAM1044. The correct orientation of the gene, which is supposed to be expressed under control of the conII promoter of pAM1044, was confirmed by restriction analysis. The conII promoter is the consensus sequence of promoters of E. coli, which contains the base sequences TTGGACA (−35) and TATAAT (−10).

The plasmid pAM1044 and the plasmid containing the codA gene were used for transformation of Synechococcus PCC7942 by the method of Elhai et al. The resultant transformant was designated as the strain PAMCOD. Synechococcus PCC7942 transformed with pAM1044 alone was used as a control and designated as the strain PAM.

Selection of the transformants was done on the BG11 agar plate containing spectinomycin at 30 μg/ml. After several inoculations of a single colony to fresh BG11 plates containing spectinomycin, the complete insertion of the spectinomycin-resistant gene and the codA gene into all the copies of the chromosomes was confirmed by PCR (Polymerase Chain Reaction) using the primers indicated in FIG. 2A. The complete insertion of the spectinomycin-resistant gene and the codA gene into the chromosomes of Synechococcus was confirmed by PCR using a combination of primers 1 and 2.

Example 2 Confirmation of the Gene Inserted into Transformants

The DNAs from the wild-type strain, the strain PAM and the strain PAMCOD of Synechococcus PCC7942 were used as templates for PCR, and the amplified products were analyzed by SDS-PAGE. The results are shown in FIG. 2B.

A PCR performed on the DNA from the wild-type strain revealed an amplified product of about 400 bp (FIG. 2B, lane b). When the DNA from the strain PAM was used as a template, a band of about 2.4 kb appeared, representing the insertion of pAM1044 into the chromosomes. The absence of the band of about 400 bp, which was observed in the wild-type strain, confirms the complete replacement of the native chromosomes by the mutated chromosomes in the strain PAM.

When the DNA from PAMCOD was used as a template, the band corresponding to the wild-type chromosomes was not observed (FIG. 2B, lane c). However, the expected band of about 4.1 kb was not amplified, either, likely due to a large size of the insert and a high GC content in the codA sequence. Therefore, primer 3 corresponding to the coding region of the codA gene (FIG. 2A) was used in combination with primer 1. The expected band of about 2.6 kb was amplified (FIG. 2B, lane d), indicating the presence of the codA gene in the chromosomes of the strain PAMCOD.

Example 3 Expression of the codA Gene in the Synechococcus Strain PAMCOD

The expression of the codA gene in the strain PAMCOD obtained in Example 1 was examined by Western blot analysis using polyclonal antiserum raised against the purified choline oxidase. The results are shown in FIG. 3. Signals were detected in the protein extracts obtained from the strain PAMCOD (lane a) and purified choline oxidase (lane c) at the position of 60 kDa. Such a signal was not detected in the protein extracts obtained from the strain PAM (lane b). This result confirms that the codA gene was expressed under control of the conII promoter in Synechococcus PCC7942.

Example 4 Analysis of Betaine Concentration in Cells

The transformed cells were grown in one liter of BG11 medium supplemented with 5 mM choline chloride. Salt stress was given by adding various concentrations of NaCl. The harvested cells were treated with 1M H₂SO₄ at 25° C. for 20 hours and betaine was recovered from the mixture by means of the periodate precipitation technique (Wall, J.S. et al., Analyt. Chem. 32:870-874, 1960). The betaine periodate was dissolved in lml of methanol-d₄ (Wako Pure Chemical Industries, Osaka, Japan) containing 2 mM 2-methyl-2-propanol (Wako Pure Chemical Industries) as an internal standard. This solution was transferred to an NMR tube and ¹H NMR spectra were measured with a Bruker AMX 360 Wb. Betaine was quantified by comparing the integrated peaks with a standard curve.

The concentration of betaine in the cells of the strain PAMCOD was determined on the basis of the cell volume estimated from the electron micrograph of negatively stained cells. The cytoplasm of a single cell had a cylindrical shape of 2.14 μm in length and 0.82 μm in diameter and the cell volume was estimated to be approximately 1.13 μm³.

The following Table 1 shows the changes in betaine concentration in the cells with the increase of NaCl concentration in the medium. Any trace of betaine could not be detected in the strain PAM lacking the codA gene. The betaine concentration in the cells of the strain PAMCOD ranged from 60 to 90 mM. Betaine accumulation in the cells of the strain PAMCOD was not significantly affected by NaCl concentration.

TABLE 1 NaCl (M) PAM (mM) PAMCOD (mM) 0 0 67 ± 3 0.2 0 73 ± 4 0.3 0 86 ± 2

Example 5 Tolerance of the Synechococcus Strain PAMCOD to salt and Osmotic Stresses

The tolerance toward salt and osmotic stresses of the cells were evaluated by measuring cell growth, chlorophyll content and photosynthetic activity. Cells of the Synechococcus strains PAM and PAMCOD were precultivated in the BG11 medium supplemented with 1 mM choline chloride at 30° C. for 3 days and the cultures were transferred to the BG11 medium supplemented with 1 mM choline chloride containing 0.4M NaCl or 0.8M sorbitol. Cell growth was monitored by optical density at 730 nm. Chlorophyll content was determined by the method described by Arnon et al. (Biochim. Biophys. Acta. 357:231-245, 1974). The photosynthetic oxygen evolution was measured by monitoring oxygen concentration with a Clark-type oxygen electrode using 1 mM 1,4-benzoquinone and 1 mM K₃Fe(CN)₆ as electron acceptors. The same cells were cultivated on the medium free from NaCl as a control.

The results of the cell growth test in the presence of NaCl are shown in FIG. 4 and the results of the cell growth test in the presence of sorbitol are shown in FIG. 5. The growth of the strain PAM was inhibited by high salt and osmotic stresses, while the strain PAMCOD could grow under these conditions.

The results of the chlorophyll content test in the presence of NaCl are shown in FIG. 6 and the results of the chlorophyll content test in the presence of sorbitol are shown in FIG. 7. The results of this test were similar to those of the cell growth test. The chlorophyll content in the strain PAM treated with a high concentration salt gradually decreased and the chlorophyll content in the strain PAM treated with 0.8M sorbitol rapidly decreased, but on the contrary, the strain PAMCOD contitued to grow even under salt or sorbitol treatment.

The results of the photosynthetic activity test in the presence of NaCl are shown in FIG. 8. Photosynthetic activity of the strain PAM was strongly inhibited by salt stress. In contrast, photosynthetic activity of the cells of the strain PAMCOD was temporarily inhibited at the early stage of salt treatment, but afterward recovered and continuously increased. The similar results were obtained in the photosynthetic activity test in the presence of sorbitol. Interestingly, the temporary decrease of photosynthetic activity was not observed when the cells of the strain PAMCOD were treated with 0.8M sorbitol.

Example 6 Preparation of a Binary Vector Plasmid Carrying the codA Gene

The rbcS (ribulose 1,5-bisphosphate carboxylase small subunit) transit signal XbaI-NdeI fragment (about 200 bp) from tobacco (Nicotiana sylvestris) was amplified by PCR using 5′ CTGTCTAGATGTAATTAACAATGGCT3′ (SEQ ID NO:3) and 5′ CCACATATGCATGCATTGCACTCT3′ (SEQ ID NO:4) as primers to introduce the XbaI and NdeI sites.

Then, the N-terminal-BamHI fragment (about 100 bp) of the codA gene was amplified by PCR using 5′ AACCATATGCACATCGACAACATC3′ (SEQ ID NO:5) and 5′ GCTCCATCCAGCGGTCCAGC3′ (SEQ ID NO:6) as primers to introduce the NdeI site. The BamHI-SmaI fragment (about 1.6 kbp) of the codA gene was prepared by restriction enzymes. Further, the SmaI-C-terminal fragment (about 80 bp) of the codA gene was amplified by PCR using 5′ GAAACAGTCCTGCTTCCACAC3′ (SEQ ID NO:7) and 5′ GCGAGCTCTGCCTACACCGCCAT3′ (SEQ ID NO:8) as primers to introduce the SacI site.

The GUS (β-glucuronidase) gene in the binary vector plasmid pBI221 was replaced by these fragments.

The restriction enzyme map of the codA gene is shown in FIG. 9.

The HindIII-EcoRI fragment containing the 35S promoter and the NOS (nopalin synthase) terminator of cauliflower mosaic virus was introduced into the binary vector plasmid pGAH to prepare the plasmid pGAH/codA (FIG. 10). This plasmid contains kanamycin- and hygromycin-resistant genes.

Example 7 Introduction of the Binary Vector Plasmid into Agrobacterium

The Agrobacterium tumefaciens EHA 101 bearing the Ti plasmid was mixed with the binary vector plasmid pGAH/codA obtained in Example 6, then freezed and thawed, and screened on the LB plate containing tetracycline and kanamycin. The resultant Agrobacterium in which the codA gene has been integrated was designated as EHA101 (pGAH/codA).

Example 8 Transformation of Arabidopsis

The Arabidopsis thaliana strain WS was germinated to prepare a hypocotyl segment. This hypocotyl was callused on B5 medium (ICN Biochemicals) (pH 5.7) containing 0.05 mg/l of kinetin (Wako Pure Chemical Industries) and 0.5 mg/l of 2,4-D (Wako Pure Chemical Industries) to form hypocotyl calli.

Then, the calli were infected with the codA-containing Agrobacterium EHA101 (pGAH/codA) prepared in Example 7 and cocultivated. After detoxification of Agrobacterium by B5 medium containing 250 mg/l of vancomycin, 500 mg/l of carbenicillin and 200 mg/l of Claforan, the cultures were transferred to a differentiation medium (B5 medium containing 25 mg/l of kanamycin and 15 mg/l of hygromycin) to form shoots. Then, kanamycin- and hygromycin-resistant shoots were selected to induce roots and to form seeds. The resultant T2 seeds are heterozygous transformed in only one of the chromosomes.

Then, the plants obtained from the T2 seeds were self-fertilized and selected by kanamycin and hygromycin to give homozygous T3 seeds.

The plants of the wild-type and transformant strains were grown in a medium (pH 5.2) containing 0.1% HYPONEX (Hyponex Corporation, Marysville, Ohio, USA) at 22° C. for 30 days on water or soil consisting of vermiculite and perlite with illumination of 75 μmol.m⁻². S⁻¹ for 16 hours in a day and in a dark room for the remaining 8 hours unless otherwise indicated, and then used for experiments.

Example 9 Immunological Study of the Expressed Choline Oxidase

An antibody was raised against choline oxidase according to the method described by the present inventors in literature (Deshniumn, P. et al., Plant Mol. Biol. 29:897-907, 1995).

Leaf from each 20-day old plant of the wild-type and transformant strains of Arabidopsis thaliana was ground in a microcentrifuge at 0° C. and the homogenates were centrifuged at 10,000× g for 10 minutes to prepare soluble fractions. The soluble protein of the supernatant was separated by SDS-PAGE and transferred to a nylon membrane (Immobilon PVDF; Millipore, Bedford, Mass., USA). The membrane was incubated with the antibody against choline oxidase and detected with a system consisting of biotinylated secondary antibody, avidin and biotinylated horse radish peroxidase (ABC Kit; Vectastain, Burlingane, Calif., USA).

The results of Western blot analysis are shown in FIG. 11. The presence of an immune responsive protein of 64 kDa corresponding to choline oxidase was identified. A small amount of protein of 70 kDa corresponding to the precursor of choline oxidase and the rbcS transit peptide were also observed. These results show that the codA gene was correctly integrated and expressed in the chromosomes and that the expressed precursor was processed into a manure protein.

Then, localization of the expressed choline oxidase in the plant was detected with the antibody against choline oxidase by a method described in literature (Mustardy, L. et al., Plant Physiol. 94:334-340, 1990). A small piece of young leaf from the plant was fixed with 1% glutaraldehyde in 0.1M sodium phosphate buffer (pH 7.2) for one hour. After rinsed with the same buffer, the sample was dehydrated with ethanol and placed in Lowicryl K4M resin (TAAB Laboratories Equipment Ltd., Berkshire, U.K.). Immuno-gold labeling was conducted by a method described in literature (Mustardy et al., supra).

As a result, the expressed choline oxidase was found to be localized in stroma of the chloroplasts, indicating that choline oxidase had been transported to the chloroplasts.

Example 10 Determination of Betaine and Chlorophyll Contents in Transformant Plants

Betaine content in leaf of the plants was calculated by measuring NMR spectra of the quaternary ammonium compound (Wall, J. et al., Analyt. Chem. 32:870-874, 1960). 5 g of leaf of the wild-type strain and transformant plants were powdered in liquid nitrogen by a ceramic motor. This powder was suspended in 25 ml of 1.0M H₂SO₄ and incubated at 25° C. for 2 hours. After unsoluble matters were removed, the supernatant was recovered by centrifugation at 1000× g for 10 minutes. The supernatant was combined with 10 ml of KI-I₂ solution and incubated at 0° C. for 2 hours. Peridodide-adducts of betaine and choline were recovered by centrifugation at 1000× g for 30 minutes and dissolved into 0.5 ml of CD₄OH (Wako Pure Chemical Industries) containing 0.5 mM 2-methyl-2-propanol (Wako Pure Chemical Industries) as an internal standard to measure ¹H NMR spectra. Two main peaks corresponding to betaine and choline were observed, and the integrated betaine peaks were used for determination of the concentration.

Chlorophyll content in leaf was measured by the following procedure. Leaf (1 g) was powdered in liquid nitrogen by a ceramic motor. The powder was suspended in 10 ml of acetone:water (4:1, v/v). After incubation for 30 minutes, unsoluble matters were removed and the supernatant was subjected to spectrophotometry (Arnon, D. I. Plant Physiol. 24:1-15, 1949).

As a result, the both of betaine and choline were observed in the transformant plant, while only choline was observed in the wild-type strain. Betaine content was 1.0 μmol/g fresh leaf. Chlorophyll content was 0.3 μmol/g fresh leaf.

Example 11 Tolerance of Transformant Arabidopsis to Salt and Osmotic Stresses

(1) Tolerance to Salt Stress

The T3 seeds obtained in Example 8 were inoculated on Murashige & Skoog's medium gelled with 0.5% gellan gum to compare germination, rooting and growth of cotyledons. On the medium free from NaCl, any difference was not found between the wild-type strain and the transformant plants. On the medium containing 60 mM sodium chloride, however, one of the transformant plants C1-0 grew relatively well to show salt tolerance as compared with the wild-type strain which poorly grew (FIG. 12).

On the medium containing 100mM sodium chloride, the wild-type strain stopped growing and its leaves whitened 10 days after germination. However, the transformant plants continued to grow while keeping green. Especially, roots of the transformant plants grew remarkably better than those of the wild-type strain. The wild-type strain and the transformant strain plants equally grew in a control test free from 100mM sodium chloride, confirming that the transformant plants gained the ability to grow under salt stress conditions.

(2) Tolerance to Osmotic Stress

The seeds of the wild-type strain and the transformant plants were sterized and inoculated on semi-solid media containing 100, 200 and 400 mM sorbitol. The cultures were placed in an incubator maintained at 22° C. with illumination of 75 μmol/m²/second for 16 hours in a day and in a dark room for the remaining 8 hours, and regularly observed. The state on the day 15 is shown in FIG. 13 (W on the left represents the wild-type strain and T on the right represents the transformant plants). At a sorbitol concentration of 100 mM, some wild-type strains showed no germination or its leaves whitened even if they germinated. However, the transformant plants continued to grow while keeping green. At a concentration of 200 mM, growth of the both strains was inhibited, but the inhibition degree of the transformant plants was lower than that of the wild-type strain, and especially, the growth of roots of the transformant plants was remarkably better than that of the wild-type strain. At a concentration of 400 mM, the wild-type strain showed no germination and the transformant plants showed no germination, either, or scarcely grew even if they germinated.

Example 12 Photosynthetic Activity of Transformant Plants Under Salt Stress

The influence of salt stress on photosynthetic system II activity of mature leaves was measured by monitoring fluorescence of chlorophyll.

The wild-type strain and the transformant strain plants grown on a control medium were transferred to HYPONEX medium containing 400 mM sodium chloride and incubated under the light or dark conditions described above. After a determined time, leaves were taken from the plants and the efficiency of photosynthetic system II was measured as a ratio of variable chlorophyll fluorescence to maximum chlorophyll fluorescence (Fv/Fm) by using a pulse intensity-modulated fluorometer (PAM-2000; Walts, Effeltrich, Germany) (Annu. Rev. Plant Physiol. Plant Mol. Biol. 42:313-349, 1991).

The results are shown in FIG. 14. After incubation for 2 days under light conditions, the wild-type strain almost lost photosynthetic system II activity, while the transformant plants maintained 50% of the original level of photosynthetic system II activity. Under dark conditions, inactivation due to salt stress was much more moderate, but photosynthetic system II activity of the transformant plants was more tolerant than that of the wild-type strain. When the plants were transferred to the medium containing 200 mM sodium chloride, the decrease of photosynthetic system II activity was much more moderate than observed on the medium containing 400 mM sodium chloride, but the transformant plants were again more tolerant to salt stress than the wild-type strain.

Example 13 Preparation of the Chimeric codA Gene Used for Transformation of Rice

Two chimeric codA genes (designated as 35SINcodA and 35SINTPcodA, respectively) which are localized on cytosol and plastid, respectively after translation of the choline oxidase gene (codA) from Arthrobacter globiformis under transcriptional control of the cauliflower mosaic virus 35S promoter were prepared on the plasmid pUC119 by the procedure described in Example 6 (see FIG. 15). Considering that the presence of an intron is required for high expression of a gene in rice (for example, see Tanaka, A. et al., Nucleic Acids Res. 18:6767-6770, 1990), an intron in the 5′ non-translated sequence of the superoxide dismutase gene of rice (SodCc2: Sakamoto, A. et al., FEBS Lett. 358:62-66, 1995) was introdued into the both chimeric genes. Further, a DNA sequence derived from the rbcS transit peptide (Coruzz, G. et al., EMBO J 3:1671-1679, 1984) from pea was added to 35SINTPcodA, in order to transfer the codA protein to the chloroplasts.

Example 14 Transformation of Rice

Each of the two chimeric codA genes prepared in Example 13 was introduced into suspension culture cells from scutellum calli of rice seeds together with the selection marker hygromycin-resistant gene by a particle gun device. The transformed calli were selected based on the antibiotic resistance and redifferentiated into a plant. Polymerase Chain Reaction (PCR) was conducted on the transformed calli or transformed/redifferentiated individuals showing hygromycine resistance, to assess integration and transcription of the codA gene into the nuclear genome by Northern blot technique and select 80 to 100 or more transformants for each codA gene.

Example 15 Analysis of Expression of the codA Gene in Transformant Rice

The transformants obtained in Example 14 were screened by Western blot technique to obtain the transformant rice (the present generation) expressing the codA gene at the protein level, ultimately including 6 individuals carrying the plastid-localized gene and 10 individuals carrying the cytosol-localized gene.

Rice lacks intrinsic choline oxidase activity, but the soluble fractions prepared from leaves or roots of the transformants showed choline oxidase activity. Contrary to expectation, all the individuals of the plastid-type transformants were found to express a lower amount of choline oxidase protein than the cytosol-type, despite the same expression promoter used.

When the expression of the codA gene was further examined by Northern blot technique, any significant difference was not found in the amount of the both genes expressed at the transcription level. When processing of the intron was examined by reverse transcriptive PCR, a plurality of splicing variants containing different 3′-acceptor sites which may not bring about normal translation into protein were detected from the mRNA transcripted from the plastid-type gene. This suggested that the low level protein expression by the plants transformed with the plastid-type gene might be due to abnormal processing of the mRNA precursor. This phenomenon seems to be related to the fact that the sequence encoding the transit peptide used for plastid-targeting of choline oxidase was derived from a dicotyledon (pea rbcS gene). Therefore, it may be readily expected that the expression of the codA in rice chloroplasts would be more efficient and the resultant transformant rice would be more tolerant to salt stress if the sequence encoding the transit peptide was derived from a monocotyledon such as rice rbcS.

Example 16 Betaine Biosynthesis in Transformant Rice

The betaine accumulating in the transformant tissue expressing choline oxidase was detected by proton NMR. FIG. 16 shows the results of the NMR of the wild-type strain, a transformant which does not express the codA gene (FIG. 16A) and a transformant which expresses the codA gene (FIG. 16B).

The transformant which expresses choline oxidase biosynthesized betaine and the amount of betaine accumulation showed a positive correlation with the amount of choline oxidase detected by Western blot technique. Betaine accumulation in leaves was higher than detected in roots and amounted to 4 μmol/g fresh leaf in individuals highly expressing the codA gene. This is the first case in which rice gained the ability to synthesize betaine through a genetic engineering procedure.

Example 17 Evaluation of Salt Tolerance of Transformant Rice

The transformant rice expressing the codA gene grew well equally to the non-transformant (wild-type) under the both of geoponic and hydroponic conditions without showing any apparent abnormality. This indicates that hydrogen peroxide formed as a by-product of betaine biosynthesis was efficiently detoxified in the cells.

Then, the transformants which could be found to express the codA gene at the level of protein, enzyme activity and betaine production were grown under the hydroponic conditions containing sodium chloride. The influence of Na salt on photosynthetic activity was assessed by chlorophyll fluorescence analysis and compared with the results of the non-transformant (wild-type). When the transformant rice and non-transformant rice were placed in aqueous HYPONEX solutions containing 100 mM and 10 mM sodium chloride and the fluorescence of chlorophyll was determined with time, the transformant was found to retard the inhibition of photosynthetic activity (FIG. 17). Thus, the transformant was found to be more tolerant in salt environment.

8 1 2400 DNA Arthrobacter globiformis CDS (361)..(2001) 1 gggaatatcc gtcgtcgtag acgagccctt cggcccgtgt aaaggtggag accttccaca 60 ccgaggacga ggccgtcgcg accgccaacg acaccaacta cgggctgtcc ggcgcggtcc 120 tggacccagg acgccggcaa gacgcagcgc gtggccggcc ggctgcgaca cggcaccgtc 180 tggatcaacg acttccaccc ctacctccca cagaccgagt ggggcggctt cggccagtcc 240 ggcgtcggcc gcgaactcgg cccgaccggc ctggccgagt accaggaggc caagcacatc 300 taccagaaca ccagcccgca ggtcaccggc tggttcgctg accacggcaa ggagaactag 360 atg cac atc gac aac atc gag aac ctg agc gac agg gag ttc gac tac 408 Met His Ile Asp Asn Ile Glu Asn Leu Ser Asp Arg Glu Phe Asp Tyr 1 5 10 15 atc gtc gtc ggc ggc ggg tcc gcc ggg gcc gcc gtc gcc gcc cgg ctg 456 Ile Val Val Gly Gly Gly Ser Ala Gly Ala Ala Val Ala Ala Arg Leu 20 25 30 agc gag gat ccc gca gtg agc gtg gcg ctg gtg gag gcc ggc ccg gat 504 Ser Glu Asp Pro Ala Val Ser Val Ala Leu Val Glu Ala Gly Pro Asp 35 40 45 gac cgc ggc gtg ccc gag gtg ctg cag ctg gac cgc tgg atg gag ctg 552 Asp Arg Gly Val Pro Glu Val Leu Gln Leu Asp Arg Trp Met Glu Leu 50 55 60 ctg gaa tcg ggc tac gac tgg gac tac ccg atc gag ccg cag gag aac 600 Leu Glu Ser Gly Tyr Asp Trp Asp Tyr Pro Ile Glu Pro Gln Glu Asn 65 70 75 80 ggc aac tcc ttc atg cgc cat gcc cgt gcc aag gtc atg ggc ggc tgc 648 Gly Asn Ser Phe Met Arg His Ala Arg Ala Lys Val Met Gly Gly Cys 85 90 95 tcc agc cac aac tcc tgc atc gcc ttc tgg gcc ccg cgc gag gac ctg 696 Ser Ser His Asn Ser Cys Ile Ala Phe Trp Ala Pro Arg Glu Asp Leu 100 105 110 gac gag tgg gag gcc aag tac ggc gcc acc ggc tgg aac gcc gag gcg 744 Asp Glu Trp Glu Ala Lys Tyr Gly Ala Thr Gly Trp Asn Ala Glu Ala 115 120 125 gcc tgg ccg ctg tac aag cgg ctg gaa acc aac gag gac gcg ggc ccg 792 Ala Trp Pro Leu Tyr Lys Arg Leu Glu Thr Asn Glu Asp Ala Gly Pro 130 135 140 gac gcg ccg cac cac ggg gac tcc ggc ccc gtg cac ctg atg aac gtg 840 Asp Ala Pro His His Gly Asp Ser Gly Pro Val His Leu Met Asn Val 145 150 155 160 ccc ccg aag gac ccg acc ggc gtc gcg ctc ctg gac gcc tgc gag cag 888 Pro Pro Lys Asp Pro Thr Gly Val Ala Leu Leu Asp Ala Cys Glu Gln 165 170 175 gcc ggc atc ccg cgc gcg aag ttc aac acc ggc acc acc gtg gtc aac 936 Ala Gly Ile Pro Arg Ala Lys Phe Asn Thr Gly Thr Thr Val Val Asn 180 185 190 ggc gcc aac ttc ttc cag atc aac cgg cgc gcg gac ggc acc cgc tcc 984 Gly Ala Asn Phe Phe Gln Ile Asn Arg Arg Ala Asp Gly Thr Arg Ser 195 200 205 tcc agc tcg gtc tcc tac atc cac ccg atc gtc gag cag gag aac ttc 1032 Ser Ser Ser Val Ser Tyr Ile His Pro Ile Val Glu Gln Glu Asn Phe 210 215 220 acc ctg cta acc ggc ctg cgc gcc cgc cag ctg gtg ttc gac gcg gac 1080 Thr Leu Leu Thr Gly Leu Arg Ala Arg Gln Leu Val Phe Asp Ala Asp 225 230 235 240 agg cgc tgc acc ggc gtc gac atc gtg gac tcc gcc ttc ggc cgc acc 1128 Arg Arg Cys Thr Gly Val Asp Ile Val Asp Ser Ala Phe Gly Arg Thr 245 250 255 cat cgg ctg acg gcg cgc aat gaa gtc gtg ctc tcc acc ggc gcg atc 1176 His Arg Leu Thr Ala Arg Asn Glu Val Val Leu Ser Thr Gly Ala Ile 260 265 270 gat acg ccg aag ctg ttg atg ctc tcc gga atc ggc ccc gcc gcc cac 1224 Asp Thr Pro Lys Leu Leu Met Leu Ser Gly Ile Gly Pro Ala Ala His 275 280 285 ctc gcc gag cac ggc atc gag gtc ctt ggt gga ctc ccc cgg cgt ggg 1272 Leu Ala Glu His Gly Ile Glu Val Leu Gly Gly Leu Pro Arg Arg Gly 290 295 300 cga gca cct gca gga cca ccc gga agg cgt ggt gca gtt cga ggc caa 1320 Arg Ala Pro Ala Gly Pro Pro Gly Arg Arg Gly Ala Val Arg Gly Gln 305 310 315 320 gca gcc cat ggt cgc cga gtc cac gca gtg gtg gga gat cgg cat ctt 1368 Ala Ala His Gly Arg Arg Val His Ala Val Val Gly Asp Arg His Leu 325 330 335 cac ccc cac cga gga cgg cct gga ccg ccc cga cct gat gat gca cta 1416 His Pro His Arg Gly Arg Pro Gly Pro Pro Arg Pro Asp Asp Ala Leu 340 345 350 cgg ctc cgt gcc gtt cga cat gaa cac cct gcg gca cgg cta ccc cac 1464 Arg Leu Arg Ala Val Arg His Glu His Pro Ala Ala Arg Leu Pro His 355 360 365 cac gga gaa cgg gct tca gcc tca ccc cga acg tca cgc acg ccc gct 1512 His Gly Glu Arg Ala Ser Ala Ser Pro Arg Thr Ser Arg Thr Pro Ala 370 375 380 ccc gcg gca ctg tcc ggc tgc gca gcc gcg act tcc gcg ata agc cca 1560 Pro Ala Ala Leu Ser Gly Cys Ala Ala Ala Thr Ser Ala Ile Ser Pro 385 390 395 400 tgg tcg acc cgc gct act tca ccg acc cag aag ggc cat gac atg cgc 1608 Trp Ser Thr Arg Ala Thr Ser Pro Thr Gln Lys Gly His Asp Met Arg 405 410 415 gtc atg gtc gcc ggc atc cgc aag gcc cgc gaa atc gcc gcc cag ccc 1656 Val Met Val Ala Gly Ile Arg Lys Ala Arg Glu Ile Ala Ala Gln Pro 420 425 430 gcc atg gcg gaa tgg acc ggc cgc gag ctc tcc ccc ggc gtc gag gcg 1704 Ala Met Ala Glu Trp Thr Gly Arg Glu Leu Ser Pro Gly Val Glu Ala 435 440 445 cag acc gac gag gag ctg cag gac tac atc cgc aag acg cac aac acc 1752 Gln Thr Asp Glu Glu Leu Gln Asp Tyr Ile Arg Lys Thr His Asn Thr 450 455 460 gtc tac cac ccc gtg ggc acc gtg cgc atg ggc gcg gtc gag gac gag 1800 Val Tyr His Pro Val Gly Thr Val Arg Met Gly Ala Val Glu Asp Glu 465 470 475 480 atg tcc ccg ctc gac ccc gag ctg cgg gtc aag ggc gtc acc ggt ctg 1848 Met Ser Pro Leu Asp Pro Glu Leu Arg Val Lys Gly Val Thr Gly Leu 485 490 495 cgc gtc ggc gac gcc tcg gtc atg ccc gag cac gtg acc gtc aac ccc 1896 Arg Val Gly Asp Ala Ser Val Met Pro Glu His Val Thr Val Asn Pro 500 505 510 aac atc acc gtc atg atg atc ggc gag cgc tgc gcg gac ctt atc cgc 1944 Asn Ile Thr Val Met Met Ile Gly Glu Arg Cys Ala Asp Leu Ile Arg 515 520 525 tcc gcc cgc gcc ggt gaa aca acg acg gcg gac gcc gag ctg agc gcg 1992 Ser Ala Arg Ala Gly Glu Thr Thr Thr Ala Asp Ala Glu Leu Ser Ala 530 535 540 gcc ctc gcc taagcgggag cggccagccg cggggcctgt ccggaaccac 2041 Ala Leu Ala 545 ctggcgggcc ccgcatgggg ccggacacaa tgccggtaac taagggtgcg gaagcagtcc 2101 tgcttccaca cccgcgtttt gcacgcccgg gccggcaact ggcccggccg gctaagccga 2161 aggtcttccg ggggcgggcc ggatcgctgc gggcagtccg tcggccagcc gctgcagcgt 2221 gccggcggta atggcggtgt aggcagggat cgcgtcgggg tagatgtact cgttgcgggc 2281 gtgcgcgccg tcgcccaccg cgcccaggcc gcacaggacc gggatgccga gggcggagac 2341 gaagttggcg tcgctgcccc cgcccaccga ggcggtttcc agctcccggc cctgctcca 2400 2 547 PRT Arthrobacter globiformis 2 Met His Ile Asp Asn Ile Glu Asn Leu Ser Asp Arg Glu Phe Asp Tyr 1 5 10 15 Ile Val Val Gly Gly Gly Ser Ala Gly Ala Ala Val Ala Ala Arg Leu 20 25 30 Ser Glu Asp Pro Ala Val Ser Val Ala Leu Val Glu Ala Gly Pro Asp 35 40 45 Asp Arg Gly Val Pro Glu Val Leu Gln Leu Asp Arg Trp Met Glu Leu 50 55 60 Leu Glu Ser Gly Tyr Asp Trp Asp Tyr Pro Ile Glu Pro Gln Glu Asn 65 70 75 80 Gly Asn Ser Phe Met Arg His Ala Arg Ala Lys Val Met Gly Gly Cys 85 90 95 Ser Ser His Asn Ser Cys Ile Ala Phe Trp Ala Pro Arg Glu Asp Leu 100 105 110 Asp Glu Trp Glu Ala Lys Tyr Gly Ala Thr Gly Trp Asn Ala Glu Ala 115 120 125 Ala Trp Pro Leu Tyr Lys Arg Leu Glu Thr Asn Glu Asp Ala Gly Pro 130 135 140 Asp Ala Pro His His Gly Asp Ser Gly Pro Val His Leu Met Asn Val 145 150 155 160 Pro Pro Lys Asp Pro Thr Gly Val Ala Leu Leu Asp Ala Cys Glu Gln 165 170 175 Ala Gly Ile Pro Arg Ala Lys Phe Asn Thr Gly Thr Thr Val Val Asn 180 185 190 Gly Ala Asn Phe Phe Gln Ile Asn Arg Arg Ala Asp Gly Thr Arg Ser 195 200 205 Ser Ser Ser Val Ser Tyr Ile His Pro Ile Val Glu Gln Glu Asn Phe 210 215 220 Thr Leu Leu Thr Gly Leu Arg Ala Arg Gln Leu Val Phe Asp Ala Asp 225 230 235 240 Arg Arg Cys Thr Gly Val Asp Ile Val Asp Ser Ala Phe Gly Arg Thr 245 250 255 His Arg Leu Thr Ala Arg Asn Glu Val Val Leu Ser Thr Gly Ala Ile 260 265 270 Asp Thr Pro Lys Leu Leu Met Leu Ser Gly Ile Gly Pro Ala Ala His 275 280 285 Leu Ala Glu His Gly Ile Glu Val Leu Gly Gly Leu Pro Arg Arg Gly 290 295 300 Arg Ala Pro Ala Gly Pro Pro Gly Arg Arg Gly Ala Val Arg Gly Gln 305 310 315 320 Ala Ala His Gly Arg Arg Val His Ala Val Val Gly Asp Arg His Leu 325 330 335 His Pro His Arg Gly Arg Pro Gly Pro Pro Arg Pro Asp Asp Ala Leu 340 345 350 Arg Leu Arg Ala Val Arg His Glu His Pro Ala Ala Arg Leu Pro His 355 360 365 His Gly Glu Arg Ala Ser Ala Ser Pro Arg Thr Ser Arg Thr Pro Ala 370 375 380 Pro Ala Ala Leu Ser Gly Cys Ala Ala Ala Thr Ser Ala Ile Ser Pro 385 390 395 400 Trp Ser Thr Arg Ala Thr Ser Pro Thr Gln Lys Gly His Asp Met Arg 405 410 415 Val Met Val Ala Gly Ile Arg Lys Ala Arg Glu Ile Ala Ala Gln Pro 420 425 430 Ala Met Ala Glu Trp Thr Gly Arg Glu Leu Ser Pro Gly Val Glu Ala 435 440 445 Gln Thr Asp Glu Glu Leu Gln Asp Tyr Ile Arg Lys Thr His Asn Thr 450 455 460 Val Tyr His Pro Val Gly Thr Val Arg Met Gly Ala Val Glu Asp Glu 465 470 475 480 Met Ser Pro Leu Asp Pro Glu Leu Arg Val Lys Gly Val Thr Gly Leu 485 490 495 Arg Val Gly Asp Ala Ser Val Met Pro Glu His Val Thr Val Asn Pro 500 505 510 Asn Ile Thr Val Met Met Ile Gly Glu Arg Cys Ala Asp Leu Ile Arg 515 520 525 Ser Ala Arg Ala Gly Glu Thr Thr Thr Ala Asp Ala Glu Leu Ser Ala 530 535 540 Ala Leu Ala 545 3 26 DNA Artificial Sequence Description of Artificial Sequenceprimer 3 ctgtctagat gtaattaaca atggct 26 4 24 DNA Artificial Sequence Description of Artificial Sequenceprimer 4 ccacatatgc atgcattgca ctct 24 5 24 DNA Artificial Sequence Description of Artificial Sequenceprimer 5 aaccatatgc acatcgacaa catc 24 6 20 DNA Artificial Sequence Description of Artificial Sequenceprimer 6 gctccatcca gcggtccagc 20 7 21 DNA Artificial Sequence Description of Artificial Sequenceprimer 7 gaaacagtcc tgcttccaca c 21 8 23 DNA Artificial Sequence Description of Artificial Sequenceprimer 8 gcgagctctg cctacaccgc cat 23 

What is claimed is:
 1. A method for producing a salt-tolerant and/or osmotolerant plant which comprises transforming a plant with a recombinant vector carrying a gene encoding choline oxidase wherein said gene comprises a base sequence encoding the amino acid sequence of SEQ ID NO. 1 or an enzymatically active fragment therefrom.
 2. A method according to claim 1 wherein the salt-tolerant and/or osmotolerant plant is a cyanobacterium.
 3. A method according to claim 1 wherein the salt-tolerant and/or osmotolerant plant is a higher plant.
 4. A method according to claim 3 wherein the higher plant is a dicotyledon.
 5. A method according to claim 4 wherein the dicotyledon is a brassicaceous plant.
 6. A method according to claim 3 wherein the higher plant is a monocotyledon.
 7. A method according to claim 6 wherein the monocotyledon is a gramineous plant.
 8. A salt-tolerant and/or osmotolerant plant produced by the method according to claim 1, or a progeny thereof having the same properties.
 9. A method for producing a salt-tolerant and/or osmotolerant rice or Arabidopsis plant which comprises transforming a plant with a recombinant vector carrying a gene encoding choline oxidase, wherein said gene comprises a base sequence encoding the amino acid sequence of SEQ ID NO. 1 or an enzymatically active fragment therefrom. 